Tumour-Suppression Function of KLF12 Through Regulation of Anoikis

Tumour-Suppression Function of KLF12 Through Regulation of Anoikis

Oncogene (2016) 35, 3324–3334 OPEN © 2016 Macmillan Publishers Limited All rights reserved 0950-9232/16 www.nature.com/onc ORIGINAL ARTICLE Tumour-suppression function of KLF12 through regulation of anoikis N Godin-Heymann1, S Brabetz1, MM Murillo1,2, M Saponaro3, CR Santos4, A Lobley5, P East5, P Chakravarty5, N Matthews6, G Kelly5, S Jordan1, E Castellano1,7 and J Downward1,2 Suppression of detachment-induced cell death, known as anoikis, is an essential step for cancer metastasis to occur. We report here that expression of KLF12, a member of the Kruppel-like family of transcription factors, is downregulated in lung cancer cell lines that have been selected to grow in the absence of cell adhesion. Knockdown of KLF12 in parental cells results in decreased apoptosis following cell detachment from matrix. KLF12 regulates anoikis by promoting the cell cycle transition through S phase and therefore cell proliferation. Reduced expression levels of KLF12 results in increased ability of lung cancer cells to form tumours in vivo and is associated with poorer survival in lung cancer patients. We therefore identify KLF12 as a novel metastasis-suppressor gene whose loss of function is associated with anoikis resistance through control of the cell cycle. Oncogene (2016) 35, 3324–3334; doi:10.1038/onc.2015.394; published online 12 October 2015 INTRODUCTION Cyclin-dependent kinase 1 (CDK1), Cyclin A/CDK2 and cylcin D are Metastasis is a multi-step process involving tumour cells leaving required for cell cycle progression and have been shown to be – their site of origin, spreading via blood or lymph vessels and essential for inducing apoptosis in some systems.5 8 forming new tumours at distant sites. Detachment-induced cell More specifically, anoikis sensitivity is associated with cell cycle death is an early step in preventing metastasis. When an regulation. Invasive and motile mesenchymal cells can survive untransformed cell detaches from its surrounding matrix or loses without ECM interactions and become arrested at the G1 stage of interaction with its neighbouring cells, it undergoes a particular cell cycle.9,10 Similarly, a population of keratinocytes that survive in type of apoptosis known as anoikis.1 Tumour cells that have the suspension undergo G0/G1 arrest,11 breast epithelial cells over- capacity to form metastasis have developed mechanisms to block expressing galectin-3 are resistant to anoikis in a manner anoikis. Improving our understanding of anoikis resistance could dependent on their arrest in G112 and mammary epithelial cells lead to the identification of novel potential therapeutic targets. can acquire anoikis resistance following a complete withdrawal The effect of the extracellular matrix (ECM) on cells is mainly from the cell cycle.13 It has been proposed that late G1 arrest is an mediated by integrins, a family of transmembrane receptors that anoikis-insensitive point.12 Brugge and colleagues have shown bind to the ECM and transduce intracellular signalling pathways. that MCF10A cells arrested in G1 or early S phase provide Upon integrin-mediated adhesion, both FAK and SRC are activated resistance to anoikis by suppressing BIM expression in a and they in turn activate various pathways such as phosphatidy- posttranscriptionally dependent manner.14 linositol 3′-kinase/AKT, RAS/RAF/MEK/extracellular signal–regu- κ The Kruppel-like family (KLF) of transcription factors regulate lated kinase (ERK) and nuclear factor- B, resulting in overall multiple processes, such as proliferation, differentiation, migration survival signals.1,2 However, when the integrin signal is lost due to and pluripotency.15 Moreover, KLF17 has been shown to be a cell detachment, these survival pathways are no longer dominant repressor of metastasis.16 KLFs can activate and repress genes that and anoikis occurs. Metastatic cells have developed various mechanisms to overcome anoikis, including epithelial-to- participate in cell cycle regulation. They can be deregulated in multiple cancers either by loss of heterozygosity, somatic mutations mesenchymal transition, changes in integrin repertoire, integrin 17 internalization, constitutive activation of pro-survival signals such or transcriptional silencing by promoter methylation. KLF12 was initially identified as a repressor for the transcription as autocrine secretion of growth factors or receptor tyrosine 18 3,4 factor AP-2α. Amplification of the chromosomal region 13q21- kinase overexpression, oxidative stress, autophagy or entosis. 19 Apoptosis has been closely linked to the cell cycle as 13q22 harbouring KLF12 occurs in salivary gland tumours and various proteins are master regulators of both processes. poorly differentiated gastric cancers have increased expression of 20 Most prominently, p53 not only regulates the G1 and G2/M KLF12 that correlate with tumour size, suggesting a possible phases of the cell cycle, the spindle checkpoint and centrosome oncogenic role. However, the same chromosomal region houses a duplication but is also a major trigger of apoptosis.5 Other regulators putative susceptibility gene in breast, prostrate and pancreatic that both stimulate proliferation as well as inducing apoptosis cancer and is the site of somatic deletions in different malignant include the Myc-Max transcription factor complex and E2F1.5 tumours.21–24 1Signal Transduction, Cancer Research UK London Research Institute, London, UK; 2The Institute of Cancer Research, London, UK; 3Mechanisms of Gene Transcription Laboratory, Cancer Research UK London Research Institute, Clare Hall Laboratories, Hertfordshire, UK; 4Translational Cancer Therapeutics, Cancer Research UK London Research Institute, London, UK; 5Bioinformatics and Biostatistics Laboratories, Cancer Research UK London Research Institute, London, UK and 6Advanced Sequencing Facility, Cancer Research UK London Research Institute, London, UK. Correspondence: Professor J Downward, Signal Transduction Laboratory Cancer Research UK, 44 Lincoln’s Inn Fields, London WC2A 3LY, UK. E-mail: [email protected] 7Present address: Centre for Cancer and Inflammation, Barts Cancer Institute, Queen Mary, University of London, Charterhouse Square, London EC1M 6BP, UK. Received 26 March 2015; revised 11 August 2015; accepted 5 September 2015; published online 12 October 2015 KLF12 loss suppresses anoikis N Godin-Heymann et al 3325 In order to identify novel regulators of anoikis, we generated In order to further characterize the PAR and SUS cell lines, we three human lung cancer sublines that were able to survive and tested the activity of core adhesion and anoikis pathways in all proliferate in suspension. Microarray analysis of these suspension three cell models growing on plastic and polyHEMA (Figure 1e). sublines relative to their parental cell lines showed that all three This analysis showed a heterogeneous result. All three cell lines had decreased expression of KLF12. Functional analysis showed adapted differently to the anchorage-independent growth condi- that knockdown of KLF12 in the parental cells could supress tion. The A549 SUS cells show elevated p-Erk levels and lower anoikis by slowing down S phase. Tail-vein assays confirmed the levels of the proapoptotic Bim protein. This mechanism of anoikis role of KLF12 as a suppressor of metastatic colony formation and resistance has already been characterized, because activated Erk1/2 phosphorylates BIM and this phosphorylation targets Bim higher expression levels of KLF12 correlate with increased survival 27 of lung cancer patients in clinical data sets. for ubiquitination and proteasomal degradation. As well as their previously observed specific metabolic phenotype, H23 SUS cells are characterized by a high p-Src level that also has been RESULTS correlated to anoikis resistance in lung adenocarcinoma cells.28 Characterizing anoikis-resistant cancer sublines H460 SUS cells show slightly higher p-Akt levels, a commonly activated pathway in anoikis resistance.2 All three cell lines have In order to further our understanding of anoikis, we generated reduced levels of phospho-FAK when grown on polyHEMA relative three anoikis-resistant human lung cancer sublines derived from to when they are grown on plastic. As they are not attached to any the well-characterized NCI-60 adherent cell lines A549, H23 and ECM when grown on polyHEMA, one would expect reduced H460. These sublines were selected by initially growing the cells to signalling from FAK in those conditions. overconfluency, collecting the floating cells and growing these in adherent conditions. This cycle was repeated 3–4 times, after which the floating cells were selected for growth in suspension on KLF12 is downregulated in all three SUS-derived cell lines polyHEMA-coated dishes to prevent the cells from adhering. Dead Although differences have been observed in metabolism and and dying cells were eliminated by growing the cells on plastic signalling in some of the SUS-derived cell lines relative to their every few passages. The three suspension-derived cell lines PAR cells, no single underlying mechanism of anoikis resistance fi differed in their macroscopic phenotype when grown on was identi ed across all three cell lines. In order to uncover such a polyHEMA-coated plates: H460 grew as single cells or pairs of mechanism of resistance, a gene expression microarray analysis cells and A549 formed small clumps, whereas H23 grew in large was performed on A549, H23 and H460 PAR cells grown on plastic clumps (Figure 1a). and SUS cells grown either on plastic or

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